Aldo Gutierrez

Domain motion in cytochrome P450 reductase: conformational equilibria revealed by NMR and small-angle x-ray scattering.

NADPH-cytochrome P450 reductase (CPR), a diflavin reductase, plays a key role in the mammalian P450 mono-oxygenase system. In its crystal structure, the two flavins are close together, positioned for interflavin electron transfer but not for electron transfer to cytochrome P450. A number of lines of evidence suggest that domain motion is important in the action of the enzyme. We report NMR and small-angle x-ray scattering experiments addressing directly the question of domain organization in human CPR. Comparison of the 1H-15N heteronuclear single quantum correlation spectrum of CPR with that of the isolated FMN domain permitted identification of residues in the FMN domain whose environment differs in the two situations. These include several residues that are solvent-exposed in the CPR crystal structure, indicating the existence of a second conformation in which the FMN domain is involved in a different interdomain interface. Small-angle x-ray scattering experiments showed that oxidized and NADPH-reduced CPRs have different overall shapes. The scattering curve of the reduced enzyme can be adequately explained by the crystal structure, whereas analysis of the data for the oxidized enzyme indicates that it exists as a mixture of approximately equal amounts of two conformations, one consistent with the crystal structure and one a more extended structure consistent with that inferred from the NMR data. The correlation between the effects of adenosine 2′,5′-bisphosphate and NADPH on the scattering curve and their effects on the rate of interflavin electron transfer suggests that this conformational equilibrium is physiologically relevant.

Electron transfer in human cytochrome P450 reductase

Cytochrome P450 reductase (CPR) is a diflavin enzyme responsible for electron donation to mammalian cytochrome P450 enzymes in the endoplasmic reticulum. Dissection of the enzyme into functional domains and studies by site-directed mutagenesis have enabled detailed characterization of the mechanism of electron transfer using stopped-flow and equilibrium-perturbation methods, and redox potentiometry. These studies and the mechanism of electron transfer in CPR are reported herein.

Kinetics of CO binding to the haem domain of murine inducible nitric oxide synthase: Differential effects of haem domain ligands

The binding of CO to the murine inducible nitric oxide synthase (iNOS) oxygenase domain has been studied by laser flash photolysis. The effect of the (6R)-5,6,7,8-tetrahydro-L-biopterin (BH(4)) cofactor L-arginine and several Type I L-arginine analogues/ligands on the rates of CO rebinding has been evaluated. The presence of BH(4) in the iNOS active site has little effect on the rebinding of protein-caged haem-CO pairs (geminate recombination), but decreases the bimolecular association rates 2-fold. Addition of L-arginine to the BH(4)-bound complex completely abolishes geminate recombination and results in a further 80-fold decrease in the overall rate of bimolecular association. Three of the Type I ligands, S-ethylisothiourea, L-canavanine and 2,5-lutidine, displaced the CO from the haem iron upon addition to the iNOS oxygenase domain. The Type I ligands significantly decreased the rate of bimolecular binding of CO to the haem iron after photolysis. Most of these ligands also completely abolished geminate recombination. These results are consistent with a relatively open distal pocket that allows CO to bind unhindered in the active site of murine iNOS in the absence of L-arginine or BH(4). In the presence of BH(4) and L-arginine, however, the enzyme adopts a more closed structure that can greatly reduce ligand access to the haem iron. These observations are discussed in terms of the known structure of iNOS haem domain and solution studies of ligand binding in iNOS and neuronal NOS isoenzymes.

Kinetics of CO binding and CO photodissociation in Pseudomonas stutzeri cd(1) nitrite reductase: probing the role of extended N-termini in fast structural relaxation upon CO photodissociation.

cd(1) nitrite reductase from Pseudomonas stutzeri is a di-haem- containing enzyme, comprising a c-type haem and a d-type haem. Studies with the highly related cd(1) nitrite reductase of Pseudomonas aeruginosa have established that this enzyme undergoes fast (microsecond) and global structural relaxation upon CO photodissociation from the reduced enzyme. A key difference between the Ps. aeruginosa and Ps. stutzeri enzyme is the absence of a flexible N-terminal extension in the Ps. stutzeri enzyme. In Ps. aeruginosa cd(1) nitrite reductase the N-terminal extension wraps around the second subunit of the homodimer and with Tyr(10) stabilizing a water molecule co-ordinated to the d(1)-haem. Given the intimate association of the N-terminal extension with the d(1)-haem, we hypothesized that the presence of the N-terminal extension likely contributes to the fast structural reorganization seen during photodissociation of CO from the reduced enzyme. In the present study we have investigated the kinetics of CO association and CO photodissociation of Ps. stutzeri cd(1) nitrite reductase (which lacks the N-terminal arm seen in the Ps. aeruginosa enzyme) to probe the role and influence of the N-terminal arm in the fast global structural reorganization seen with Ps. aeruginosa. Surprisingly, we find that Ps. stutzeri cd(1) nitrite reductase also undergoes fast structural reorganization during CO photodissociation. We also show, in stopped-flow experiments, that the kinetics of CO binding and dissociation with reduced Ps. stutzeri cd(1) nitrite reductase are similar to those observed with Ps. aeruginosa enzyme, thus ruling out a major role for the N-terminal flexible arm found in Ps. aeruginosa in the kinetics of these processes. Our data indicate that global structural reorganization following CO photodissociation is an intrinsic property of the haem domains in cd(1) nitrite reductases. The absence of an N-terminal extension, as in the Ps. stutzeri cd(1) nitrite reductase, does not lead to loss of global structural reorganization following CO photodissociation.